---
layout: default
title: Pose
parent: Solutions
has_children: true
has_toc: false
nav_order: 5
---
# MediaPipe Pose
{: .no_toc }
Table of contents
{: .text-delta }
1. TOC
{:toc}
[`mAP`] | Yoga
[`PCK@0.2`] | Dance
[`mAP`] | Dance
[`PCK@0.2`] | HIIT
[`mAP`] | HIIT
[`PCK@0.2`]
----------------------------------------------------------------------------------------------------- | -----------------: | ---------------------: | ------------------: | ----------------------: | -----------------: | ---------------------:
BlazePose.Heavy | 68.1 | **96.4** | 73.0 | **97.2** | 74.0 | **97.5**
BlazePose.Full | 62.6 | **95.5** | 67.4 | **96.3** | 68.0 | **95.7**
BlazePose.Lite | 45.0 | **90.2** | 53.6 | **92.5** | 53.8 | **93.5**
[AlphaPose.ResNet50](https://github.com/MVIG-SJTU/AlphaPose) | 63.4 | **96.0** | 57.8 | **95.5** | 63.4 | **96.0**
[Apple.Vision](https://developer.apple.com/documentation/vision/detecting_human_body_poses_in_images) | 32.8 | **82.7** | 36.4 | **91.4** | 44.5 | **88.6**
![pose_tracking_pck_chart.png](../images/mobile/pose_tracking_pck_chart.png) |
:--------------------------------------------------------------------------: |
*Fig 2. Quality evaluation in [`PCK@0.2`].* |
We designed our models specifically for live perception use cases, so all of
them work in real-time on the majority of modern devices.
Method | Latency
Pixel 3 [TFLite GPU](https://www.tensorflow.org/lite/performance/gpu_advanced) | Latency
MacBook Pro (15-inch 2017)
--------------- | -------------------------------------------------------------------------------------------: | ---------------------------------------:
BlazePose.Heavy | 53 ms | 38 ms
BlazePose.Full | 25 ms | 27 ms
BlazePose.Lite | 20 ms | 25 ms
## Models
### Person/pose Detection Model (BlazePose Detector)
The detector is inspired by our own lightweight
[BlazeFace](https://arxiv.org/abs/1907.05047) model, used in
[MediaPipe Face Detection](./face_detection.md), as a proxy for a person
detector. It explicitly predicts two additional virtual keypoints that firmly
describe the human body center, rotation and scale as a circle. Inspired by
[Leonardo’s Vitruvian man](https://en.wikipedia.org/wiki/Vitruvian_Man), we
predict the midpoint of a person's hips, the radius of a circle circumscribing
the whole person, and the incline angle of the line connecting the shoulder and
hip midpoints.
![pose_tracking_detector_vitruvian_man.png](../images/mobile/pose_tracking_detector_vitruvian_man.png) |
:----------------------------------------------------------------------------------------------------: |
*Fig 3. Vitruvian man aligned via two virtual keypoints predicted by BlazePose detector in addition to the face bounding box.* |
### Pose Landmark Model (BlazePose GHUM 3D)
The landmark model in MediaPipe Pose predicts the location of 33 pose landmarks
(see figure below).
Please find more detail in the
[BlazePose Google AI Blog](https://ai.googleblog.com/2020/08/on-device-real-time-body-pose-tracking.html),
this [paper](https://arxiv.org/abs/2006.10204) and
[the model card](./models.md#pose), and the attributes in each landmark
[below](#pose_landmarks).
![pose_tracking_full_body_landmarks.png](../images/mobile/pose_tracking_full_body_landmarks.png) |
:----------------------------------------------------------------------------------------------: |
*Fig 4. 33 pose landmarks.* |
## Solution APIs
### Cross-platform Configuration Options
Naming style and availability may differ slightly across platforms/languages.
#### static_image_mode
If set to `false`, the solution treats the input images as a video stream. It
will try to detect the most prominent person in the very first images, and upon
a successful detection further localizes the pose landmarks. In subsequent
images, it then simply tracks those landmarks without invoking another detection
until it loses track, on reducing computation and latency. If set to `true`,
person detection runs every input image, ideal for processing a batch of static,
possibly unrelated, images. Default to `false`.
#### model_complexity
Complexity of the pose landmark model: `0`, `1` or `2`. Landmark accuracy as
well as inference latency generally go up with the model complexity. Default to
`1`.
#### smooth_landmarks
If set to `true`, the solution filters pose landmarks across different input
images to reduce jitter, but ignored if [static_image_mode](#static_image_mode)
is also set to `true`. Default to `true`.
#### min_detection_confidence
Minimum confidence value (`[0.0, 1.0]`) from the person-detection model for the
detection to be considered successful. Default to `0.5`.
#### min_tracking_confidence
Minimum confidence value (`[0.0, 1.0]`) from the landmark-tracking model for the
pose landmarks to be considered tracked successfully, or otherwise person
detection will be invoked automatically on the next input image. Setting it to a
higher value can increase robustness of the solution, at the expense of a higher
latency. Ignored if [static_image_mode](#static_image_mode) is `true`, where
person detection simply runs on every image. Default to `0.5`.
### Output
Naming style may differ slightly across platforms/languages.
#### pose_landmarks
A list of pose landmarks. Each landmark consists of the following:
* `x` and `y`: Landmark coordinates normalized to `[0.0, 1.0]` by the image
width and height respectively.
* `z`: Represents the landmark depth with the depth at the midpoint of hips
being the origin, and the smaller the value the closer the landmark is to
the camera. The magnitude of `z` uses roughly the same scale as `x`.
* `visibility`: A value in `[0.0, 1.0]` indicating the likelihood of the
landmark being visible (present and not occluded) in the image.
### Python Solution API
Please first follow general [instructions](../getting_started/python.md) to
install MediaPipe Python package, then learn more in the companion
[Python Colab](#resources) and the usage example below.
Supported configuration options:
* [static_image_mode](#static_image_mode)
* [model_complexity](#model_complexity)
* [smooth_landmarks](#smooth_landmarks)
* [min_detection_confidence](#min_detection_confidence)
* [min_tracking_confidence](#min_tracking_confidence)
```python
import cv2
import mediapipe as mp
mp_drawing = mp.solutions.drawing_utils
mp_pose = mp.solutions.pose
# For static images:
IMAGE_FILES = []
with mp_pose.Pose(
static_image_mode=True,
model_complexity=2,
min_detection_confidence=0.5) as pose:
for idx, file in enumerate(IMAGE_FILES):
image = cv2.imread(file)
image_height, image_width, _ = image.shape
# Convert the BGR image to RGB before processing.
results = pose.process(cv2.cvtColor(image, cv2.COLOR_BGR2RGB))
if not results.pose_landmarks:
continue
print(
f'Nose coordinates: ('
f'{results.pose_landmarks.landmark[mp_holistic.PoseLandmark.NOSE].x * image_width}, '
f'{results.pose_landmarks.landmark[mp_holistic.PoseLandmark.NOSE].y * image_height})'
)
# Draw pose landmarks on the image.
annotated_image = image.copy()
mp_drawing.draw_landmarks(
annotated_image, results.pose_landmarks, mp_pose.POSE_CONNECTIONS)
cv2.imwrite('/tmp/annotated_image' + str(idx) + '.png', annotated_image)
# For webcam input:
cap = cv2.VideoCapture(0)
with mp_pose.Pose(
min_detection_confidence=0.5,
min_tracking_confidence=0.5) as pose:
while cap.isOpened():
success, image = cap.read()
if not success:
print("Ignoring empty camera frame.")
# If loading a video, use 'break' instead of 'continue'.
continue
# Flip the image horizontally for a later selfie-view display, and convert
# the BGR image to RGB.
image = cv2.cvtColor(cv2.flip(image, 1), cv2.COLOR_BGR2RGB)
# To improve performance, optionally mark the image as not writeable to
# pass by reference.
image.flags.writeable = False
results = pose.process(image)
# Draw the pose annotation on the image.
image.flags.writeable = True
image = cv2.cvtColor(image, cv2.COLOR_RGB2BGR)
mp_drawing.draw_landmarks(
image, results.pose_landmarks, mp_pose.POSE_CONNECTIONS)
cv2.imshow('MediaPipe Pose', image)
if cv2.waitKey(5) & 0xFF == 27:
break
cap.release()
```
### JavaScript Solution API
Please first see general [introduction](../getting_started/javascript.md) on
MediaPipe in JavaScript, then learn more in the companion [web demo](#resources)
and the following usage example.
Supported configuration options:
* [modelComplexity](#model_complexity)
* [smoothLandmarks](#smooth_landmarks)
* [minDetectionConfidence](#min_detection_confidence)
* [minTrackingConfidence](#min_tracking_confidence)
```html